PSI AP Physics B
Kinematics
Multiple-Choice Questions
1. An object moves around a circular path of radius R. The object starts from
point A, goes to point B and describes an arc of half of the circle. Which of
the following is true about the magnitude of displacement and traveled
distance?
Displacement
Traveled Distance
A. R
2𝜋 R
B. 4R
πR
C. 2R
πR
D.
𝑅
2
R
E.
R
4πR
2. A rock is thrown straight up from the edge of a cliff. The rock reaches the maximum height of 15 m above the
edge and then falls down to the bottom of the cliff 35 m below the cliff. What is the traveled distance of the
rock?
A. 15 m
B. 30 m
C. 35 m
D. 50 m
E. 65 m
3. A rock is thrown straight up from the edge of a cliff. The rock reaches the maximum height of 15 m above the
edge and then falls down to the bottom of the cliff 35 m below the cliff. What is the displacement of the rock?
A. 15 m
B. 30 m
C. 35 m
D. 50 m
E. 65 m
4. Can an object’s velocity equal zero when object’s speed is greater than zero?
A. Yes, when the object moves in a straight line at a constant rate
B. Yes, when the accelerates in a straight line in one direction
C. Yes, when the object returns to its original position
D. No, it is impossible because they are always equal
E. No, it is impossible because the magnitude of the velocity is always greater that speed
5. A car accelerates from rest at a constant rate 5 m/s2. Which of the following statements is true?
A. The car travels 5 m in every second
B. The car travels 10 m in every second
C. The car decreases its velocity 5 m/s in every second
D. The car increases its velocity 5 m/s in every second
D. The car’s velocity doesn’t change
6. Position as a function of time of a moving object is presented by the graph. Which of the following is true about
the type of motion?
I.
The object moves with a constant positive acceleration
II.
The object moves with a constant positive velocity
III.
The slope of this graph is equal to the object’s acceleration
IV.
The slope of this graph is equal to the object’s velocity
V.
The area under this graph is equal to the object’s velocity
A. I and II
B. II and IV
C. I, II and V
D. III and V
E. I and V
7. Position as a function of time of two moving objects is presented by
the graph. Which of the following statements is true?
I.
Object I has a greater velocity than object II
II.
Object II has a greater velocity that object I
III.
At time t0 they have the same velocity
IV.
At time t0 object II passes by object I
A. I
D. I, II and III
B. III
C. I and III
E. II and IV
An object is thrown straight up with an initial velocity v0. The graph represents
the object’s vertical displacement as a function of time. Use the graph to the
right for questions 8 through 10.
8. What is the total flying time of the object?
A. 2 s
B. 4 s
C. 6 s
D. 8 s
9. At what time the object reaches its maximum height?
A. 2 s
B. 4 s
C. 6 s
D. 8 s
10. What is the initial velocity v0 of the object?
A. 20 m/s
B. 40 m/s
C. 60 m/s
E. 5 s
E. 5 s
D. 80 m/s
E. 50 m/s
11. Which of the following graphs represents the velocity as a function of time of an object thrown straight up?
A.
B.
C.
D.
E.
12. Which of the following graphs represents the acceleration as a function of time of an object thrown straight up?
A.
B.
C.
D.
E.
The relationship between the position and time of a moving
object is shown on the graph. Use this graph for questions 13
and 14.
13. What is the instantaneous speed of the object at 4 s?
A. 1 m/s
B. 2 m/s
C. 3 m/s
D. 4 m/s
E. 5 m/s
14. During which of the following times does the object
accelerate?
A. 0 s to 2 s
B. 2 s to 4 s
C. 0 s to 4 s
D. 4 s to 8 s
E. 0 s to 8 s
The graph to the right describes the relationship
between velocity and time for a moving object. Use
this graph for questions 15 through 20.
15. What is the acceleration at time t = 1 s?
A. 4 m/s2
B. 2 m/s2
C. -2 m/s2
D. -4 m/s2
E. 0 m/s2
16. What is the acceleration at time t = 8 s?
A. 4 m/s2
B. 2 m/s2
C. -2 m/s2
2
2
D. -4 m/s
E. 0 m/s
17. What is the acceleration at time t = 6 s?
A. 1 m/s2
B. 2 m/s2
C. 3 m/s2
D. -4 m/s2
E. 0 m/s2
18. What is the total displacement for the
entire trip?
A. 18 m
B. 12 m
C. 6 m
D. 30 m
E. 0 m
19. What is the total traveled distance for the entire trip?
A. 18 m
B. 12 m
C. 6 m
D. 30 m
E. 0 m
20. Between what times does the object approach the origin at the constant speed?
A. 0 s to 2 s
B. 2 s to 5 s
C. 6 s to 7 s
D. 7 s to 9 s
E. 9 s to 10 s
21. A rock is thrown straight up with twice the initial velocity of another. How much higher will the first rock be at its
apex?
A. 2 times
B. 8 times
C. 4 times
D. 16 times
E. The rocks will reach the same apex point
22. A student drops a pebble from the edge of a vertical cliff. The pebble hits the ground 4 s after it was dropped.
What is the speed of the pebble just before it hits the ground?
A. 20 m/s
B. 40 m/s
C. 60 m/s
D. 80 m/s
100 m/s
23. A student drops a pebble from the edge of a vertical cliff. The pebble hits the ground 4 s after it was dropped.
What is the height of the cliff?
A. 20 m
B. 40 m
C. 60 m
D. 80 m
E. 100 m
24. An Astronaut on the Moon simultaneously drops a bird feather and a screw driver. The fact that two objects
reach the surface at the same time can be explained by which of the following?
A. The Moon has no gravity
B. The Moon’s gravity is much weaker than the Earth’s gravity
C. The screw driver and the feather are weightless on the Moon
D. The same gravitational force is applied on both objects on the Moon
E. At the given location all objects fall with the same acceleration in the absence of air resistance
25. A marble launcher shoots a marble horizontally from the height of 0.2 m above a horizontal floor. The marble
lands on the floor 5 m away from the launcher. How long did the marble stay in are?
A. 0.1 s
B. 0.2 s
C. 0.3 s
D. 0.4 s
E. 0.5 s
26. A marble launcher shoots a marble horizontally from the height of 0.2 m above a horizontal floor. The marble
lands on the floor 5 m away from the launcher. What is the initial speed of the marble?
A. 5 m/s
B. 10 m/s
C. 15 m/s
D. 20 m/s
E. 25 m/s
27. A bicyclist moves a long a straight line with an initial velocity v0 and slows down. Which of the following the best
describes the signs set for the initial position, initial velocity and the acceleration?
Initial position
Initial velocity
Acceleration
A.
Positive
Negative
Negative
B.
Positive
Positive
Negative
C.
Negative
Positive
Negative
D.
Negative
Negative
Positive
E.
Negative
Negative
Negative
28. Which of the following is a vector quantity?
A. Traveled distance
B. Displacement
C. Area
29. Which of the following is not a vector quantity?
A. Velocity
B. Displacement
C. Force
D. Mass
D. Momentum
A vector of displacement D is placed in X-Y coordinate system
shown in the diagram to the right. Use this diagram to answer
questions 30 though
30. What is the x-component of vector D?
A. 1 m
B. 2 m
C. 3 m
D. 4 m
E. 5 m
31. What is the y-component of vector D?
A. 1 m
B. 2 m
C. 3 m
D. 4 m
E. 5 m
32. What is the magnitude of vector D?
A. 1 m
B. 2 m
C. 3 m
D. 4 m
E. 5 m
E. Volume
E. Traveled distance
33. An object changes its velocity from V1 to V2 during a time interval Δt. Which of the following is the correct
direction for the object’s acceleration?
A.
C.
b.
D.
E.
34. A projectile is fired at 60 ̊ above the horizontal line with an initial
velocity v0. At which of the following angles the projectile will land
at the same distance as it is landed in the first trial?
A. 20 ̊
B. 30 ̊
C. 40 ̊
D. 45 ̊
E. 50 ̊
35. When a projectile reaches the highest point the vertical component of the acceleration is:
A. Less than g
B. Greater than g
C. Positive g
D. Negative g
E. Zero
36. When a projectile reaches the highest point the horizontal component of the acceleration is:
A. Less than g
B. Greater than g
C. Positive g
D. Negative g
E. Zero
37. A projectile is fired from the ground level with an initial
velocity v0. Which of the following statements is true?
I.
Vertical component of the velocity at point C is v0 sinθ
II.
Horizontal component of the velocity at point C is zero
III.
The projectile travels with the same speed at point B
and D
IV.
The acceleration at point C is zero
A. I and II
D. Only III
B. II and III
C. Only IV
E. III and IV
38. An object is thrown in horizontal with an initial velocity v0= 5 m/s from the roof of a building 40 m tall. How
much later does it hit the ground?
A. 2 s
B. 4 s
C. √5 s
D. √8 s
E. 10 s
39. An object is thrown in horizontal with an initial velocity v0= 10 m/s from the roof of a building 20 m tall. How far
from the building does it hit the ground?
A. 5 m
B. 10 m
C. 12 m
D. 15 m
E. 20 m
The diagram to the right
represents a swimmer. The
swimmer is capable to swim in a
still water with a velocity V1 = 1
m/s. He aims his body directly
across a 100 m wide river whose
current has a velocity V2 = 2 m/s.
Use this diagram to answer
questions 40 through
40. How much time it will take for the swimmer to cross the river?
A. 10 s
B. 20 s
C. 50 s
D. 60 s
E. 100 s
41. How far downstream will he land?
A. 100 m
B. 200 m
C. 150 m
D. 180 m
E. 120 m
42. What is the velocity of the swimmer relative to the river bank?
A. 1 m/s
B. 2 m/s
C. 3 m/s
D. √3 m/s
E. √5 m/s
Free Response Problems
1. A car whose speed is 20 m/s passes a stationary motorcycle which immediately gives chase with a
constant acceleration of 2.4 m/s2.
a. How far will the motorcycle travel before catching the car?
b. How fast will it be going at that time?
c. How does that compare to the car’s velocity?
d. Draw the following graphs for the car: x(t), v(t), a(t).
e. Draw the following graphs for the motorcycle: x(t), v(t), a(t).
f. Write the equation of motion for the car.
g. Write the equation of motion for the motorcycle.
2. A lab cart moves a long a straight
horizontal track. The graph describes
the relationship between the velocity
and time of the cart.
a. Indicate every time interval
for which speed
(magnitude of the velocity)
of the cart is decreasing.
b. Indicate every time at
which the cart is at rest.
c. Determine the horizontal
position x of the cart at t = 4 s if the cart is located at x0 = when t0 = 0.
d. Determine the traveled distance of the cart over 10 s from the beginning.
e. Determine the average speed of the cart for this time interval.
f. Find the acceleration of the cart during time: 0 s -4 s, 4 s – 8 s, 8 s – 10 s, 10 s – 14 s, 14 s – 16
s, 16 s – 20 s.
g. On the axes below, sketch the acceleration graph for the motion of the cart from t = 0 s to t =
20 s.
3. Find the magnitude and the direction of vector C for the following cases.
a. A = 10 N at 0 ̊, B = 20 N at 0 ̊, C = A + B
b. A = 10 N at 0 ̊, B = 20 N at 180 ̊, C = A + B
c. A = 10 N at 180 ̊, B = 20 N at 180 ,̊ C = A + B
d. A = 10 N at 0 ̊, B = 20 N at 90 ̊, C = A + B
e. A = 10 N at 90 ̊, B = 20 N at 0 ̊, C = A + B
4. Find the magnitude and the direction of vector G as a sum of two vectors D and E by going through the
following steps.
a. D = 10 N at 37 ̊. Find Dx and Dy.
b. E = 20 N at 25 ̊. Find Ex and Ey.
c. Find Gx = Dx + Ex
d. Find Gy = Dy + Ey
e. Find the magnitude of G from its components
f. Find the direction of G.
5. Find the magnitude and the direction of vector C for the following cases.
a. A = 40 N at 0 ̊, B = 10 N at 0 ̊, C = A + B
b. A = 40 N at 0 ̊, B = 10 N at 180 ̊, C = A + B
c. A = 40 N at 180 ̊, B = 10 N at 180 ,̊ C = A + B
d. A = 40 N at 0 ̊, B = 10 N at 90 ̊, C = A + B
e. A = 40 N at 90 ̊, B = 10 N at 0 ̊, C = A + B
6. Find the magnitude and the direction of vector G as a sum of two vectors D and E by going through the
following steps.
a. D = 30 N at 65 ̊. Find Dx and Dy.
b. E = 45 N at 15 ̊. Find Ex and Ey.
c. Find Gx = Dx + Ex
d. Find Gy = Dy + Ey
e. Find the magnitude of G from its components
f. Find the direction of G.
7. Two forces 300 N at 0 ̊ and 400 N at 90 ̊pull on an object. Answer the following:
a. Draw a diagram showing the forces acting on the object.
b. Draw a sketch showing the vector sum of two forces.
c. Find the magnitude of the resultant force.
d. Find the direction of the resultant force.
8. A ship makes three displacements in the following order:
1) 76 mi, 48 ̊ north of east
2) 50 mi, 56 ̊north of west; and
3) 47 mi, south
a. Draw a clear diagram showing all three displacement vectors with respect to horizontal points
(north, east, south, and west).
b. Find the X and Y components of displacement D1.
c. Find the X and Y components of displacement D2.
d. Find the X and Y components of displacement D3.
e. Find the magnitude of the resultant vector.
f. Find the direction of the resultant vector.
9. A bus makes three displacements I the following order:
4) 58 mi, 38 ̊ east of north
5) 69 mi, 46 ̊ west of north; and
6) 75 mi, south-east
a. Draw a clear diagram showing all three displacement vectors with respect to horizontal points
(north, east, south, and west).
b. Find the X and Y components of displacement D1.
c. Find the X and Y components of displacement D2.
d. Find the X and Y components of displacement D3.
e. Find the magnitude of the resultant vector.
f. Find the direction of the resultant vector.
10. A ball is thrown horizontally from the roof of a building 75 m tall with a speed of 4.6 m/s.
a. How much later does the ball hit the ground?
b. How far from the building will it land?
c. What is the velocity of the ball just before it hits the ground?
11. A projectile is fired with an initial speed of 150 m/s at an angle of 47 ̊ above the horizontal.
a. Determine the total time in the air.
b. Determine the maximum height reached by the projectile.
c. Determine the maximum horizontal distance covered by the projectile.
d. Determine the velocity of the projectile 5 s after firing.
12. A projectile is fired from the edge of a cliff 95 m high with an initial speed of 50 m/s at an angle of 37 ̊
above the horizontal.
a. Determine the total time in the air.
b. Determine the maximum height reached by the projectile.
c. Determine the maximum horizontal distance covered by the projectile.
d. Determine the velocity of the projectile just before it hits the bottom of the cliff.
13. A ball is thrown horizontally from the roof of a building 55 m tall with a speed of 3.8 m/s.
a. How much later does it hit the ground?
b. How far from the building will it land?
c. What is the velocity of the ball just before it hits the ground?
14. A projectile is fired with an initial speed of 110 m/s at an angle of 36 above the horizontal.
a. Determine the total time in the air.
b. Determine the maximum height reached by the projectile.
c. Determine the total horizontal distance covered by the projectile.
d. Determine the velocity of the projectile 4s after firing.
15. A ball rolls off a 1.5 m tall horizontal table and lands on the floor .70 m away.
a. How much time is the ball in the air?
b. How does that time compare with the time it takes for a dropped ball to fall that same
distance.
c. What is the ball’s velocity while it was on the table top?
d. What is the horizontal component of its velocity just prior to impact/
e. What is the vertical component of its velocity just prior to impact?
f. What is the magnitude of its velocity just prior to impact?
g. What is the direction of its velocity just prior to impact?
16. An archer fires an arrow with a velocity of 42 m/s at an angle of 35 degrees above horizontal?
a. What is the horizontal component of its initial velocity?
b. What is the vertical component of its initial velocity?
c. What is the maximum height attained by the arrow?
d. How long does it take the arrow to reach that height?
e. What is the total amount of time that it’s in the air?
f. How far away does it strike the ground?
g. What is the horizontal component of its velocity just prior to impact?
h. What is the vertical component of its velocity just prior to impact?
i. What is the magnitude of its velocity just prior to impact?
j. What is the direction of its velocity just prior to impact?
17. A cannon is fired horizontally from a cliff 112m high with a speed of 25 m/s.
a. How much later does the cannon ball hit the ground?
b. How far from the cliff will it land?
c. What is the velocity of the cannon ball just before it hits the ground?
18. A ball is thrown horizontally from the roof of a building 12 m tall with a speed of 3.1 m/s.
a. How much later does the ball hit the ground?
b. How far from the building will it land?
c. What is the velocity of the ball just before it hits the ground?
19. A gazelle leaps from a cliff 2.5 m high with a speed of 5.6 m/s.
a. How much later does the gazelle hit the ground?
b. How far from the cliff will it land?
c. What is the velocity of the gazelle just before it hits the ground?
20. A projectile is fire with an initial speed of 40 m/s at an angle of 23 above the horizontal.
a. Determine the total time in the air.
b. Determine the maximum height reached by the projectile.
c. Determine the maximum horizontal distance covered by the projectile.
d. Determine the velocity of the projectile 2s after firing.
21. A hose held near the ground shoots water at a speed of 3.5 m/s at an angle of 72 above the horizontal.
a. Determine the total time of the water in the air.
b. Determine the maximum height reached by the water.
c. Determine the maximum horizontal distance covered by the water.
d. Determine the velocity of the water 1.5s after firing.
22. A soccer ball is kicked with a speed of 4.8m/s at an angle of 45 above the horizontal.
a. Determine the total time in the air.
b. Determine the maximum height reached by the ball.
c. Determine the maximum horizontal distance covered by the ball.
d. Determine the velocity of the projectile 3s after firing.
23. A projectile is fired from the edge of a cliff 40 m high with an initial speed of 18 m/s at an angle of2
above the horizontal.
a. Determine the total time in the air.
b. Determine the maximum height reached by the projectile.
c. Determine the maximum horizontal distance covered by the projectile.
d. Determine the velocity of the projectile just before it hits the bottom of the cliff.
24. A projectile is fired from the edge of a cliff 20 m high with an initial speed of 12 m/s at an angle of 41
above the horizontal.
a. Determine the total time in the air.
b. Determine the maximum height reached by the projectile.
c. Determine the maximum horizontal distance covered by the projectile.
d. Determine the velocity of the projectile just before it hits the bottom of the cliff.
25. A football is kicked from a height of .85 m with an initial speed of 5.2 m/s at an angle of 50 above the
horizontal.
a. Determine the total time in the air.
b. Determine the maximum height reached by the football.
c. Determine the maximum horizontal distance covered by the football.
d. Determine the velocity of the projectile just before it hits the bottom of the cliff.
Answers
Free Response
Multiple Choice
1. a. 333 m
b. 40 m/s
c. twice the speed
1.
2.
3.
4.
5.
6.
7.
8.
9.
10.
11.
12.
13.
14.
15.
16.
17.
18.
19.
20.
21.
22.
23.
24.
25.
26.
27.
28.
29.
30.
31.
32.
33.
34.
35.
36.
37.
38.
39.
40.
41.
42.
C
E
C
C
D
B
E
D
B
B
C
B
B
D
B
E
D
C
D
D
C
B
D
E
B
C
D
B
E
C
D
E
D
B
D
E
D
D
E
E
B
E
e. 68.3 N
f. 34.6o
7. a.
d.
e.
𝑚
𝑠
f. 𝑥 = (20 ) 𝑡
1
𝑚
g. 𝑥 = 2 (2.4 𝑠2 ) 𝑡
2. a. 8 to 10 s
b. 10 to 14 s
c. 8 m
d. 28 m
e. 2.8 m/s
f. 1 m/s2, 0, -2 m/s2, 0, -1 m/s2, 0
3.
4.
5.
6.
g.
a. 30N at 0o
b. 10N at 180o
c. 30N at 180o
d. 22.4N at 63o
e. 22.4 at 26.6o
a. 8.0 N and 6.0 N
b. 18.1 N and 8.5 N
c. 26.1 N
d. 12.7 N
e. 29 N
f. 25.9 o
a. 50 N at 0o
b. 30 N at 0o
c. 50 N at 180o
d. 41.2 N at 14o
e. 41.2 N at 76o
a. 12.7 N and 27.2 N
b. 43.5 N and 11.6 N
c. 56.2 N
d. 38.8 N
b.
c. 500 N
d. 53.1o
8. a.
b. 50.9 mi and 56.5 mi
c. -27.9 mi and 41.5 mi
d. 0 mi and -47 mi
e. 55.9 mi
f. 65.7o North of East
9. a.
b. 35.7 mi and 45.7 mi
c. -49.6 mi and 47.9 mi
d. 53.0 mi and -53.0 mi
e. 56.4 mi
f. 46.1o
10. a. 3.9 s
b. 18 m
c. 39.3 m/s at 305 o
11. a. 2 s
b. 614 o
c. 2244 m
d. 118 m
12. a. 8.4 s
b. 14 m
c. 335.2 m/s
d. 65.7 m/s at 54 o